A team of the Department of Inorganic and Organic Chemistry and the Institute of Theoretical and Computational Chemistry of the UB (IQTCUB), together with a research group of biological chemistry of the University of Oxford, have synthetized carbohydrates with enzymes.
Barcelona/Spain — Sugar or carbohydrate synthesis is important for the development of diagnostic tests, vaccines and new drugs. Sugar or carbohydrate synthesis in the laboratory (conventional chemical synthesis) is usually expensive and requires a lot of work; therefore lots of efforts have been made over the last years to do so with enzymes, which are natural catalysers. However, the enzymes that synthetize sugar (called glycosyltransferases) are hard to manipulate. This is an obstacle for the development of potential drugs that could be used to treat numerous diseases related to carbohydrate-active enzymes, such as diabetes or certain types of cancer.
Nowadays the classic idea of carbohydrates being a source of energy has changed. People know now that carbohydrates play an essential role in many molecular processes in the cell, from detecting pathogenic agents to cellular communication or anti-inflammatory response. Therefore there is a great interest in the design of drugs that copy the structure of carbohydrates, since they would be easily assimilated and recognized by a part of the biological receptor system.
New enzymes that go from degrading to synthetizing carbohydrates
Now the teams of the University of Barcelona and Oxford have found the way to modify an enzyme (glycosidase) which usually degrades carbohydrates (it catalyses the hydrolysis in glycosidic bonds) so that it acts reversely and synthetises carbohydrates. “Moreover, this synthesis has been reached with a new reaction that had not been observed in glycosidase yet. This is a variation from a reaction called front-face or SNi-like” says Carme Rovira. “The advantage of this reaction in glycosidase –continues the researcher- is that it makes the synthesis in a clean way, without almost causing hydrolysis residues and using economically viable substrates (sugar)”.
“Basically, we used our experience with enzymes that synthetize carbohydrates to apply the reaction to one side in other enzymes with more biotechnological possibilities” concluded the researcher. Her team discovered the molecular bases of the one side mechanism in enzymes in 2001.
In the study, the synthesis has been carried out with a specific enzyme, the Sulfolobus solfataricus beta-glycosidase, but it can be applied to other enzymes using a similar engineering method of the active center.
The study, published in the journal Nature Chemical Biology, has been led by the researcher Carme Rovira, Icrea researcher from the Department of Inorganic and Organic Chemistry of the UB, and Benjamin G. Davis, from the University of Oxford. Javier Iglesias-Fernández — researcher in training at the UB and first author of the study in which the supercomputer Mare Nostrum (from Barcelona Supercomputing Center, BSC-CNS) was used to create multi-scale molecular dynamics simulations — also participated in the study.
J. Iglesias-Fernández, S. M. Hancock, S. S. Lee, M. Khan, J. Kirkpatrick, N. J. Oldham, K. McAuley, A. Fordham-Skelton, C. Rovira and B. G. Davis. «A front-face ‘SNi synthase’ engineered from a retaining ‘double-SN2’ hydrolase». Nature Chemical Biology, Juny de 2017. Doi: 10.1038/nchembio.2394
L. Raich, C. Rovira. «Desxifrant mecanismes enzimàtics per mitjà d’eines computacionals: implicacions biotecnològiques en l’estudi de glicosidases». Catalan Society of Chemistry journal, issue number 15 (2016), p. 9-20.